Transmission slot allocation method and map for virtual tunnels in a transmission line

ABSTRACT

In accordance with one embodiment of the present invention, a map of transmission slots for a port of a network element includes a plurality of hierarchical sets of port transmission slots. The hierarchical sets include a plurality of parent sets. Each parent set has its port transmission slots divided between a plurality of child sets. The child sets include interleaved port transmission slots.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.09/325,497, filed Jun. 3, 1999 now U.S. Pat. No. 6,665,301 and entitled“TRANSMISSION SLOT ALLOCATION METHOD AND MAP FOR VIRTUAL TUNNELS IN ATRANSMISSION LINE”.

This application is related to copending U.S. application Ser. No.09/997,626, filed Nov. 28, 2001 and entitled “METHOD AND SYSTEM FORTRANSMITTING TRAFFIC IN A VIRTUAL TUNNEL OF A TRANSMISSION LINE”, whichis a continuation of U.S. application Ser. No. 09/325,687 filed Jun. 3,1999 and entitled “METHOD AND SYSTEM FOR TRANSMITTING TRAFFIC IN AVIRTUAL TUNNEL OF A TRANSMISSION LINE”.

TECHNICAL FIELD OF THE INVENTION

This invention relates generally to the field of telecommunicationsystems, and more particularly to a transmission slot allocation methodand map for virtual tunnels in a transmission line.

BACKGROUND OF THE INVENTION

Telecommunications networks have traditionally been circuit-switchnetworks that have transmission paths dedicated to specific users forthe duration of a call and that employ continuous, fixed-bandwidthtransmission. Due to growth in data traffic created by the Internet andits related technologies, however, telecommunications networks are beingmoved to a packet-switching transmission model. Packet-switch networksprovide a large range of digital services, from data to video to basicvoice telephony. Packet-switch networks can allow dynamic bandwidth andmay be connectionless with no dedicated path or connection-oriented withvirtual circuits and dedicated bandwidth along a predetermined path.

Asynchronous transfer mode (ATM) is a connection-orientedpacket-switching technology in which information is organized intosmall, fixed length cells. ATM carries data asynchronously,automatically assigning data cells to available time slots on demand toprovide maximum throughput. Compared with other network technologies,ATM provides large increases in maximum supported bandwidth, designed-inisosynchronous traffic support, support for multiple types of trafficsuch as data, video, and voice transmissions on shared communicationlines, and virtual networking capabilities, which increase bandwidthutilization and ease network administration.

ATM cells are routed through a telecommunications network at high speedsusing a switching label included in the cell. The switching label hastwo sections that define a virtual path (VP) and a virtual channel (VC)in the network through which the cell is routed. The use of virtualpaths and virtual channels allows physical bandwidth in the network tobe subdivided and separately commercialized.

Because of the low latency and predictability throughput ATM offers, itis capable of providing quality of service (QoS) features. QoS isdefined in terms of the attributes of end-to-end ATM connections and isimportant in an integrated service network, particularly fordelay-sensitive applications such as audio and video transmissions, aswell as voice-over IP. Other applications in which QoS may be importantinclude traditional data communications, imaging, full-motion video, andmultimedia, as well as voice.

Performance criteria for describing QoS for a particular connectioninclude cell loss rate (CLR), cell transfer delay (CTD), and cell delayvariation (CDV). ATM traffic is classified as either constant bit rate(CBR) traffic, real-time or non real-time variable bit rate (VBR)traffic, available bit rate (ABR) traffic, and unspecified bit rate(UBR) traffic, depending on the QoS parameters applied to the traffic.CBR and VBR traffic utilize dedicated bandwidth and are intended forreal time applications. ABR traffic is intended for non-real timeapplications which can control, on demand, their transmission rate in acertain range. Like ABR, UBR traffic is intended for non-real timeapplications which do not have any constraints on the cell delay andcell delay variations.

For CBR, VBR, and other traffic having dedicated bandwidth, transmissionslots can be spaced throughout a frame in the transmission line tominimize cell delay variation. However, ABR, UBR, and other types ofdynamic bandwidth traffic are evaluated based on transmission lineconstraints and transmitted in time slots as they become available. As aresult, such traffic typically has a high cell delay variation.

SUMMARY OF THE INVENTION

The present invention provides a transmission slot allocation method andmap that substantially eliminate or reduce the disadvantages andproblems associated with previous systems and methods. In particular,the map stores predefined sets of interleaved port transmission slotsthat can be assigned to dedicated or dynamic bandwidth traffic.

In accordance with one embodiment of the present invention, a map oftransmission slots for a port of a network element includes a pluralityof hierarchical sets of port transmission slots. The hierarchical setsinclude a plurality of parent sets. Each parent set has its porttransmission slots divided between a plurality of child sets. The childsets include interleaved port transmission slots.

More specifically, in accordance with a particular embodiment of thepresent invention, the hierarchical sets each include substantiallyevenly spaced port transmission slots. In this and other embodiments,each parent set is divided into a same number of child sets. Thehierarchical sets may also include a plurality of base sets each havinga number of port transmission slots corresponding to a base transmissionrate for the port.

Technical advantages of the present invention include providing animproved method and map for allocating bandwidth of a transmission lineto a virtual interface. In particular, port transmission slots aregrouped into a plurality of hierarchical sets having interleaved porttransmission slots. The hierarchical sets can be dynamically allocatedto a virtual interface to provide transmission slots for any supportedbandwidth. In addition, the transmission slots in each set aresubstantially evenly spaced throughout the transmission frame of theport. This provides minimal delay variation for both dedicated anddynamic bandwidth traffic, and for multiple virtual interfaces operatingat different rates. The hierarchical sets are also sized to be equal toor only slightly larger than a supported transmission rate. As a result,allocatable bandwidth is maximized.

Other technical advantages of the present invention will be readilyapparent to one skilled in the art from the following figures,description, and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention and itsadvantages, reference is now made to the following description taken inconjunction with the accompanying drawings, wherein like referencenumerals represent like parts, in which:

FIG. 1 is a block diagram illustrating a telecommunications system inaccordance with one embodiment of the present invention;

FIG. 2 is a block diagram illustrating an add/drop multiplexer elementfor the telecommunications system of FIG. 1 in accordance with oneembodiment of the present invention;

FIG. 3 is a block diagram illustrating a line card for the add/dropmultiplexer of FIG. 2 in accordance with one embodiment of the presentinvention;

FIG. 4 is a schematic diagram illustrating a map of port transmissionslots for the line card of FIG. 3 in accordance with one embodiment ofthe present invention;

FIG. 5 is a flow diagram illustrating a method for generating the map ofFIG. 4 in accordance with one embodiment of the present invention;

FIG. 6 is a flow diagram illustrating a method for selecting evenlyspaced transmission slots for generation of the map of FIG. 4 inaccordance with one embodiment of the present invention; and

FIG. 7 is a flow diagram illustrating the operation of the add/dropmultiplexer of FIG. 2 in accordance with one embodiment of the presentinvention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates a telecommunications system 10 in accordance with oneembodiment of the present invention. In this embodiment, thetelecommunications system 10 comprises a public portion 12 and a privateportion 14 that each transmit voice, data, other suitable types ofinformation, and/or a combination of different types of information. Thepublic portion 12 includes a public network 20 such as the Internet. Theprivate portion 14 includes remote private networks 22 and 24. Theprivate networks 22 and 24 are each an Intranet or other suitablenetwork such as a private local area network (LAN) or a private widearea network (WAN). The telecommunications system 10 may be entirelyimplemented in either the public network 20 or in one of the privatenetworks 22 or 24, or may be otherwise suitably distributed betweendisparate networks.

Referring to FIG. 1, the telecommunications system 10 includes aplurality of nodes 26 interconnected by transmission lines 28. The nodes26 each comprise a network element capable of communicating traffic inthe telecommunications system 10. The network element may be a switch,router, add/drop multiplexer or other suitable device capable ofdirecting traffic in the telecommunications system 10.

The transmission lines 28 provide a physical interface between the nodes26. Each physical interface is defined by the bandwidth of theconnecting transmission line 28 which may be a DS-3 line, an OC-3 line,an OC-12 line, or any other suitable bandwidth. The transmission lines28 each comprise optical fiber, cable, twisted wire, or other suitablewireline or wireless link capable of transporting traffic between twonodes 26.

For the embodiment of FIG. 1, the telecommunications system 10 includesa private boundary node 30 (“Node A”) at a boundary of the privatenetwork 22, a public boundary node 32 (“Node B”) at a first boundary ofthe public network 20, an intermediate node 34 within the public network20, a public boundary node 36 (“Node C”) at a second boundary of thepublic network 20, and a private boundary node 38 (“Node D”) at aboundary of the private network 24. The nodes 30, 32, 34, 36, and 38 areeach asynchronous transport mode (ATM) elements or multi-protocolelements having functionality for processing ATM traffic in whichinformation is organized into small, fixed length cells. The ATM cellsare routed by the nodes 30, 32, 34, 36, and 38 using switching labelsincluded in the cell. The switching label has two sections that define avirtual path (VP) and a virtual channel (VC) in the telecommunicationssystem 10 through which the cell is routed. Use of virtual paths (VPs)and virtual channels (VCs) allows physical bandwidth of thetelecommunications system 10 to be subdivided and separatelycommercialized.

A virtual channel (VC) 40 is formed in the transmission line 28 betweenNodes A and B. The virtual channel (VC) 40 forms a public universalnetwork interface (UNI) 42 between Node A in the private network 22 andNode B in the public network 20. Similarly, a virtual channel (VC) 44 isformed in the transmission line 28 between Nodes C and D. The virtualchannel (VC) 44 forms a public universal network interface (UNI) 46between Node C in the public network 20 and Node D in the privatenetwork 24. Virtual channels (VCs) 40 and 44 together with virtualchannels (VCs) 48 in the public network 20 between Nodes B and C form avirtual tunnel 50 between Nodes A and D. The virtual tunnel 50 is avirtual channel (VC), virtual path (VP), or any other suitable portionand/or construct of one or more transmission lines 28. The virtualtunnel 50 together with a virtual interface 52 at the entrance to thevirtual tunnel 50 and a termination interface 54 at the end of thevirtual tunnel 50 forms a virtual network network interface (V-NNI)between Nodes A and D. Nodes B and C need not know of the virtualnetwork network interface (V-NNI). The virtual interface 52 aggregatesand transmits traffic designating the virtual tunnel 50. Trafficdesignates the virtual tunnel 50 when the traffic includes informationindicating that it is to be transmitted in the virtual tunnel 50. Thetermination interface 54 separates traffic received from the virtualtunnel 50 for individualized routing. Accordingly, virtual channelconnections (VCCs) 56 can be transmitted through the telecommunicationssystem 10 in the virtual tunnel 50 and need not compete with otherdesignated traffic outside of the virtual tunnel 50 and inside thesystem 10.

FIG. 2 illustrates details of Node A in accordance with one embodimentof the present invention. In this embodiment, Node A is a multi-protocoladd/drop multiplexer 80. As described in more detail below, the add/dropmultiplexer 80 includes a plurality of transmission line interfaces thateach independently queue and schedule traffic for a transmission line ora virtual tunnel in a transmission line. Remaining Nodes B, C, D, and Emay be similarly configured.

Referring to FIG. 2, the add/drop multiplexer 80 comprises a servicecomplex 82, a transport complex 84, switch complex 86, a managementcomplex 88, and a synchronization complex 90. The disparate complexes82, 84, 86, 88, and 90 are interconnected by one or more networks orbackplanes in the add/drop multiplexer 80.

The service complex 82 includes a plurality of tributary cards 92. Thetributary cards 92 each receive customer input/output (I/O) and performconversions necessary for processing by the switch complex 86.

The transport complex 84 includes a plurality of line cards 94 fortransmitting data on the transmission lines 95. In a particularembodiment, the line cards 94 are OC-3 or OC-12 line cards that arebi-directional and can handle optical to electrical (O/E) and electricalto optical (E/O) conversions. In this embodiment, the line cards 94 alsohandle the line and selection overhead extraction and insertion.

For the embodiment of FIG. 2, the transport complex 84 also includes aninterface controller 96 and an interface array 98 comprising a pluralityof transmission line interfaces 100. The interface controller 96 isimplemented by software stored in a computer-readable medium forexecution by a processor of the add/drop multiplexer 80. Thecomputer-readable medium is a random access memory (RAM), a read onlymemory (ROM), or other suitable medium capable of storing instructionsfor execution by a processor. The interface array 98 is implemented byan application specific integrated chip (ASIC), software, or acombination of hardware and software. Both the interface controller 96and interface array 98 may, in another embodiment, be separatelyimplemented in each of the line cards 94, or for each port of the linecards 94.

As described in more detail below, the interface controller 96 isoperable to generate a port memory map for each port of the transportcomplex 84 and to couple transmission line interfaces 100 from theinterface array 98 to the ports of the line cards 94. A transmissionline interface 100 is coupled to a port when it is connected to the portfor use as a physical interface in connection with a transmission line95 or as a virtual interface in connection with a virtual tunnel in thetransmission line 95. An interface is physical when it is for a physicalrate of a port or virtual when for a virtual rate of the port. Thetransmission line interface 100 is coupled to the port by a dedicated orother suitable bus or by dedicated or other suitable lines and/orswitches. The interface controller 96 is also operable to selectivelyallocate port transmission slots from the port memory map to thetransmission line interfaces 100 coupled to the port. Accordingly, theinterface controller 96 can dynamically implement and size virtualinterfaces in each of the outlet ports of the add/drop multiplexer 80.

The switch complex 86 comprises a plurality of switch fabric cardsincluding an ATM switch fabric card. The ATM switch fabric card receivesATM cells on an input port and switches them to an output port. Inswitching the ATM cells, the switch complex 86 first translatesnecessary virtual path (VP) and virtual channel (VC) addresses.

The management complex 88 monitors and controls the status of theservice, transport, switch, and synchronization complexes 82, 84, 86,and 90. The management complex 88 also maintains alarm, protectionswitching, and provisioning databases for the add/drop multiplexer 80.The synchronization complex 90 synchronizes the service, transport, andswitch complexes 82, 84, and 86 by providing a stable traceablereference clock.

FIG. 3 illustrates an ATM switch fabric 102 for use in the add/dropmultiplexer 80 in accordance with one embodiment of the presentinvention. In this embodiment, the ATM switch fabric 102 comprises aplurality of ATM output ports 104 for connection to disparatetransmission lines 106. The outlet ports 104 each receive ATM trafficfrom the switch complex 86 of the add/drop multiplexer 80 and transmitthe traffic in a corresponding transmission line 106. The ATM trafficcomprises dedicated traffic such as constant bit rate (CBR) traffic andreal-time and non real-time variable bit rate (VBR) traffic, as well asdynamic traffic such as available bit rate (ABR) traffic and unspecifiedbit rate (UBR) traffic. Dynamic traffic is traffic that is subject tochange, has bandwidth that can be shared between connections, and/or hasan unspecified rate within a range. The constant bit rate (CBR),real-time variable bit rate (VBR), and other dedicated traffic utilizesubstantially constant and/or dedicated bandwidth and are intended forreal time applications such as audio, video, and voice-over IPtransmissions. The dynamic traffic is generally bursty in nature. Theavailable bit rate (ABR) traffic is intended for real time applicationswhich can control, on demand, their transmission rate in a certainrange. The unspecified bit rate (UBR) traffic is intended for non-realtime applications which do not have any constraints on cell delay andcell delay variation. Quality of service (QoS) levels are defined foreach traffic type based on cell loss rate (CLR), cell transfer delay(CTD), and cell delay variation (CDV).

Referring to FIG. 3, the outlet ports 104 each include one or moreinterfaces 114 and 118 and a port memory map 112. Each interface 114 or118 is defined by a transmission line interface 100 of the interfacearray 98 coupled to the port 104. The transmission line interfaces 100form virtual interfaces 114 for virtual tunnels 116 in the transmissionline 106 and physical interfaces 118 for the physical bandwidth of thetransmission line 106. The virtual interfaces 114 each transmit trafficdesignating a corresponding virtual tunnel 116 that is defined by aportion of the bandwidth of the transmission line 106. The physicalinterfaces 118 each transmit traffic of the port 104 in the bandwidth ofthe transmission line 106.

The virtual and physical interfaces 114 and 118 each comprise a queue120 and a scheduler 122. The queue 120 receives designated virtualchannel connections (VCC) of any designated class and temporarily storesthe traffic for the scheduler 122. The scheduler 122 shapes traffic fromthe queue 120 and transmits the traffic in the transmission line 106 orthe virtual tunnel 116 of the transmission line 106. In shaping thetraffic, the scheduler 122 aggregates virtual channel connection (VCC)traffic in a corresponding transmission line 106 and virtual tunnel 116and ensures that the sum of aggregate virtual channel connection (VCC)traffic does not exceed the transmission line rate of the correspondingvirtual tunnel 116. The virtual and physical interfaces 114 and 118 mayalso include back pressure transmission rate adaptation buffers toaccount for the egress rate of the scheduler 122 not exactly matchingthe physical link rate due to limited schedule table length and thelike.

For a virtual interface 114, the scheduler 122 transmits traffic fromthe queue 120 in a set of port transmission slots allocated to theinterface 114 from the port memory map 112. The allocated porttransmission slots define the virtual tunnel 116 corresponding to thevirtual interface 114. The capacity of the virtual interface is equal tothe transmission line rate of the virtual tunnel 116. The scheduler 122ensures the transmission line rate allocated to the virtual tunnel 116is not exceeded. For the physical interfaces 118, the scheduler 122transmits traffic from the queue 120 in the port transmission slotsrepresenting physical bandwidth. Accordingly, the physical interface 118uses the physical bandwidth of the corresponding transmission line 106.

For the embodiment of FIG. 3, the bandwidth of a first transmission line106 is entirely subdivided into a plurality of virtual tunnels 116. Forexample, the first transmission line 106 may be an OC-3c transmissionline subdivided into three disparate virtual tunnels 116, comprisingtransmission rates of 100 Mbps, 35 Mbps, and 20 Mbps, respectively. Tosupport this configuration, the port 104 includes separate virtualinterface 114 for each virtual tunnel 116. The bandwidth of a secondtransmission line 132 is subdivided into a virtual tunnel 116 and aremaining portion 134 that transmits traffic of the port 104 notdesignating the virtual tunnel 116. For example, the second transmissionline 132 may be an OC-3c transmission line comprising a 20 Mbps virtualtunnel 116. To support this configuration, the port 104 includesseparate virtual interfaces 114 for the virtual tunnel 116 and theremaining bandwidth of the transmission line 106. The interface of theremaining bandwidth is illustrated as a physical interface to illustratethat concept.

FIG. 4 illustrates the details of a port memory map 140 for each port104 of the ATM switch fabric 102 in accordance with one embodiment ofthe present invention. In this embodiment, transmission slots of a portare grouped based on a base transmission rate for the port. The basetransmission rate is a foundation rate for the port 104 or virtualtunnels 116 supported by the port 104. The base transmission shouldprovide the desired granularity for assignable bandwidth. The basetransmission rate is preferably the lowest transmission rate of the portor of a virtual tunnel supported by the port and may be a standardizedrate such as the DS-1 rate or other suitable rate.

Referring to FIG. 4, port memory map 140 comprises a plurality ofhierarchal sets 142 of port transmission slots. The hierarchical sets142 are arranged in a series of hierarchical levels 145 with a pluralityof hierarchical sets 142 in one level 145 together containing the porttransmission slots of a hierarchical set 142 in a next higher level 145.The port transmission slots are the transmission slots available to theport 104 for transmission of traffic in a connected transmission line106. Accordingly, the number of port transmission slots varies with thebandwidth of the transmission line 106. For example, a port 104 adaptedfor connection to an OC-3 transmission line 106 comprises 4,096 porttransmission slots while a port 104 adapted for connection to an STS-1transmission line 106 comprises 1,365 transmission slots.

The hierarchal sets 142 of port transmission slots include a pluralityof parent sets 144. Each parent set 144 has its port transmission slotsequally divided between a plurality of child sets 146, which maythemselves be parent sets 144 to further child sets 146. The porttransmission slots of the parent sets 144 are interleaved between thechild sets 146 to maintain substantially equal spacing between thetransmission slots in each set 144 and 146. Unless otherwise specified,the term each means every one of at least a subset of the identifieditems. For a parent set 144 having two child sets 146, for example, eachchild set 146 preferably has every other port transmission slot of theparent set 144.

For the embodiment of FIG. 4, the port memory map 140 comprises 4,096port transmission slots for an OC-3 port. Each parent set 144 is dividedinto two child sets 146. The base sets 148 each comprise forty-one (41)port transmission slots corresponding to a base DS-1 transmission rate.The number of transmission slots correspond to a transmission rate whenthe number of transmission slots is substantially a minimum numbernecessary to support the rate. The substantial minimum number necessaryto support the rate is the smallest integer number of slots that resultsin a transmission rate equal to or slightly larger than the actual rate.

The hierarchical sets 142 are segregated into primary hierarchical sets150 and secondary hierarchical sets 152. The primary hierarchical sets150 comprise a maximum number of port transmission slots that can berecursively divided evenly to reach the base set 148. For the base DS-1sets 148 in the illustrated embodiment, the primary hierarchical sets150 comprise 2,624 port transmission slots. The secondary hierarchicalsets 152 comprise the remaining 1,472 port transmission slots of theOC-3 bandwidth.

The primary hierarchical sets 150 comprise an initial set (P₆₄) at afirst primary level 145. The initial set (P₆₄) includes all of the 2,624port transmission slots of the primary hierarchical sets 150. Asdescribed in more detail below, these port transmission slots aresubstantially equally spaced throughout the port transmission frame toprovide minimal cell delay variation (CDV). The initial set (P₆₄) isdivided into two child sets (P₃₂₋₁ and P₃₂₋₂) each having a disparateinterleaved half of the port transmission slots of the initial set(P₆₄). Accordingly, the port transmission slots in the child sets (P₃₂₋₁and P₃₂₋₂) remain substantially equally spaced. The child sets (P₃₂₋₁and P₃₂₋₂) are divided into further child sets (P₁₆₋₁ . . . P₁₆₋₄) whichare recursively divided into further child sets (P₈₋₁ . . . P₈₋₈, P₄₋₁ .. . P₄₋₁₆, P₂₋₁ . . . P₂₋₃₂, and P₁₋₁ . . . P₁₋₆₄) until basetransmission sets (P₁₋₁ . . . P₁₋₆₄) are reached. The resulting primarysets 150 each have substantially evenly spaced transmission slots andrepresent a particular bandwidth in the transmission line. Accordingly,a primary set 150 can be allocated to a virtual interface 114 to providedesired bandwidth with minimal cell delay variation (CDV).

The secondary hierarchical sets 152 comprise a plurality of tiers 154each comprising a maximum number of remaining port transmission slotsthat can be recursively divided evenly to reach the base set 148. Theport transmission slots in each tier 154 are evenly spaced to the extentpossible to minimize cell delay variation (CDV). In each tier 154, aspreviously described in connection with the primary hierarchical sets150, an initial set (S₃₂, S₂, or S₁) is recursively divided into twochild sets 146 until the base set 148 is reached. Each child set 146comprises an interleaved half of the port transmission slots of theparent set 144.

Each hierarchical set 142, whether parent or child 144 or 146 or primaryor secondary 150 or 152 can be allocated to a scheduler 122 of atransmission line interface 100 coupled to the port 104. To optimizecell delay variation for the interface 100, each is preferably assigneda single hierarchical set 142. However, multiple hierarchical sets 142can be assigned as needed to optimize bandwidth usage.

FIG. 5 is a flow diagram illustrating a method for generating the portmemory map 140 for a port 104 in accordance with one embodiment of thepresent invention. In this embodiment, the port 104 has a number oftransmission slots that cannot be recursively divided evenly to yieldthe base set 148. Accordingly, the port memory map 140 will include bothprimary and secondary sets 150 and 152. In other embodiments in whichthe total number of port transmission slots can be recursively andevenly divided to reach the base set 148, all resulting sets may beprimary sets 150 with optimized spacing. Also in this embodiment, theport memory map 140 is generated by the interface controller 96 in theadd/drop multiplexer 80. The port memory map 140 may be independentlygenerated and provided to the add/drop multiplexer 80 for the port 104.

Referring to FIG. 5, the method begins at step 160 in which the numberof port slots in a base set 148 is obtained. The number of port slotscorrespond to a base transmission rate for the port 104. As previouslydescribed, the base transmission rate is the foundation rate for theport 104 or a virtual tunnel 116 supported by the port 104.

Proceeding to step 162, the number of port transmission slots for theprimary hierarchical sets 150 is determined. This number comprises amaximum number of port transmission slots that can be recursivelydivided evenly to reach the base set 148. For the embodiment of FIG. 4in which each parent set 144 is divided into two child sets 146, thenumber of port transmission slots for the primary hierarchical sets 150is the largest 2N multiple of the number of port transmission slots in abase set 148 that is less than or equal to the total number of porttransmission slots.

Next, at step 164, the determined number of port transmission slots forthe primary hierarchical sets 150 are selected as an initial set fromthe entirety of the port transmission slots. The selected porttransmission slots are substantially evenly spaced to provide minimalcell delay variation (CDV) for the primary hierarchical sets 150.Further details for selecting substantially evenly spaced porttransmission slots are described below in connection with FIG. 6.

At step 166, the initial set is divided into two child sets 146. Eachchild set 146 has a disparate interleaved half of the port transmissionslots of its parent set 144. Next, at step 168, each child set 146 isrecursively divided into two lower-level 145 child sets 146 until thechild sets 146 in a lowest level 145 are base sets 148. Accordingly,each of the primary hierarchical sets 150 correspond to a base rate oris a multiple of the base rate.

Proceeding to step 170, a number of port transmission slots for a nexttier 154 of secondary hierarchical sets 152 is determined. The next tiersecondary hierarchical sets 152 comprise a maximum number of remainingport transmission slots that can be recursively divided evenly to reachthe base set 148. The remaining port transmission slots are transmissionslots of the port 104 not previously selected for the primaryhierarchical sets 150 or a previous tier 154 of secondary hierarchicalsets 152.

At step 172, the determined numbered port transmission slots for thenext tier secondary hierarchical sets 152 are selected as an initial setfrom the remaining port transmission slots. The selected porttransmission slots are evenly spaced in the port transmission frame tothe extent possible to minimize cell delay variation (CDV) for the nexttier secondary hierarchical sets 152. Further details for selecting theport transmission slots are described below in connection with FIG. 6.

Proceeding to step 174, the initial set is divided into two child sets146. Each child set 146 has a disparate interleaved half of the porttransmission slots of its parent set 144. At step 176, each child set146 is recursively divided into two lower-level 145 child sets 146 untilthe child sets in a lowest level 145 are base sets 148. Accordingly,each secondary hierarchical set 152 correspond to a base transmissionrate or is a multiple of the base transmission rate.

Proceeding to decisional step 178, the interface controller 98determines whether the number of unselected port transmission slots arecapable of supporting additional base sets 148. If the unselected porttransmission slots are capable of supporting additional base sets 148,the remaining port transmission slots can be further grouped intohierarchical sets 142 and the Yes branch of decisional step 178 returnsto step 170 where the number of port transmission slots for the nexttier of secondary hierarchical sets 152 is determined. After all porttransmission slots capable of supporting a base set 148 have beenselected, the No branch of decisional step 178 leads to step 180. Atstep 180, the remaining port transmission slots are selected as aremainder set that can be combined with one or more of the hierarchicalsets 142 to increase the bandwidth of a virtual tunnel 116, be used as alimited non-standard virtual tunnel 116, or be otherwise suitably usedas needed to transport data from the port 104.

Next, at step 182, the initial, child, and remainder sets are saved to acomputer readable medium as the port memory map 140. In this way, porttransmission slots are grouped into a plurality of hierarchical sets 142having interleaved port transmission slots. The hierarchical sets 142can be dynamically allocated to virtual or physical interfaces 114 or118 to provide transmission slots for any supportive bandwidth. Thehierarchical sets 142 are also sized to be equal to or only slightlylarger than a base transmission rate. As a result, allocatable bandwidthin a transmission line 106 is maximized.

FIG. 6 is a flow diagram illustrating a method for selectingsubstantially evenly spaced transmission slots for the primary andsecondary sets 150 and 152 of the port memory map 140 in accordance withone embodiment of the present invention. The method may be used to mapany lower rate map of transmission slots into a higher rate map oftransmission slots.

Referring to FIG. 6, the method begins at step 200 in which a number ofport transmission slots to be selected for a lower rate map is obtained.For the port memory map 140, the lower rate map may be the primaryhierarchical sets 150 or a tier of secondary hierarchical sets 152.

Proceeding to step 202, the number of port transmission slots availablein a higher rate map for allocation to the lower rate map is obtained.For the primary hierarchical sets 150, the number of port transmissionslots available for allocation to the primary hierarchical sets 150comprise the total number of transmission slots for the port 104.Accordingly, spacing may be optimized for the primary hierarchical set150. For a tier of secondary hierarchical sets 152, the number of porttransmission slots available for allocation to the secondaryhierarchical sets 152 comprise the remaining transmission slots of theport that have not been previously allocated to the primary hierarchicalsets 150 or previous tiers of secondary hierarchical sets 152.

Next, at step 204, an average slot interval is obtained. As used herein,obtained means determined or received. In one embodiment, the averageslot interval comprises the ratio of the number of port transmissionslots available for selection in the higher rate map divided by thenumber of port transmission slots to be selected for the lower rate map.

Proceeding to step 206, a starting position in the higher rate map isobtained. In one embodiment, the starting position is the firstavailable port transmission slot in the higher rate map. At step 208,the port transmission slot at the starting position is selected as thefirst port transmission slot for the lower rate map.

At step 210, an estimated position of a next port transmission slot isgenerated by incrementing the position of the previous port transmissionslot by the average slot interval. Accordingly, port transmission slotsfor the lower rate map are each separated by the average interval toprovide optimized cell delay variation. At step 212, the next porttransmission slot is selected based on the estimated position. In oneembodiment, a floor position is determined from a floor function of theestimated position. In this embodiment, the transmission slot at thefloor position is selected as the next port transmission slot.

Proceeding to decisional step 214, it is determined whether all of theport transmission slots have been selected for the lower rate map. Ifall of the port transmission slots have not yet been selected, the Nobranch of decisional step 214 returns to step 210 where an estimatedposition of the next port transmission slot is generated. After all ofthe port transmission slots have been selected, the Yes branch ofdecisional step 214 leads to the end of the process. In this way, porttransmission slots are selected by the interface controller 96 or otherdevice during generation of the port memory map 104 or for other lowerrate maps in a higher rate map. The transmission slots are substantiallyevenly spaced to the extent possible throughout the transmission frameof the port. This provides minimal cell delay variation for bothdedicated and dynamic bandwidth traffic, and for multiple virtualinterfaces operating at different rates.

FIG. 7 is a flow diagram illustrating operation of the add/dropmultiplexer 80 in accordance with one embodiment of the presentinvention. In this embodiment, the add/drop multiplexer 80 processes ATMtraffic including a plurality of virtual channel connections (VCCs)designating a virtual tunnel 116 in a transmission line 106 connected toan outlet port 104 of the multiplexer 80. The virtual tunnel 116 iscontrolled by a virtual interface 114 and defined by a hierarchical set142 of port transmission slots allocated to the virtual interface 114.

Referring to FIG. 7, the method begins at step 250 in which the add/dropmultiplexer 80 receives disparate virtual channel connections (VCCs)designating the virtual tunnel 116 from one or more sources. At step252, the add/drop multiplexer 80 translates necessary virtual path (VP)and virtual channel (VC) addresses for the virtual channel connections(VCCs). Based on the translated address, the add/drop multiplexer 80switches the VCCs to the virtual interface 114 for the virtual tunnel116.

Proceeding to step 256, the virtual channel connections (VCCs) areaggregated in the queue 120 of the virtual interface 114. The virtualchannel connections (VCCs) may include dedicated traffic such asconstant bit rate (CBR) or real-time variable bit rate (VBR) traffic ordynamic traffic such as available bit rate (ABR) traffic or unspecifiedbit rate (UBR) traffic. At step 258, the scheduler 122 for the virtualinterface 114 schedules the virtual channel connections (VCCs) fortransmission within the port transmission slots of the allocatedhierarchical set 142. The port transmission slots define the virtualtunnel 116. Accordingly, the virtual channel connections (VCCs) need notcompete with other traffic in the transmission line 106.

Proceeding to step 260, scheduled traffic is transmitted in the virtualtunnel 116 of the transmission line 106. The traffic may travel in thevirtual tunnel 116 to a next node or through a plurality of intermediatenodes to a remote termination node. At step 262, the virtual channelconnections (VCCs) are separated and individually routed. In this way,dynamic traffic is transported within a virtual tunnel, and can even becombined with dedicated or other dynamic traffic sources. As a result,virtual tunnels can be used for all types of traffic and quality ofservice (QoS) levels can be provided for dynamic traffic. This allows atelecommunications provider to better package resources and to bettersupport its customers whose dynamic traffic no longer need compete withthat of other businesses.

Although the present invention has been described with severalembodiments, various changes and modifications may be suggested to oneskilled in the art. It is intended that the present invention encompasssuch changes and modifications as fall within the scope of the appendedclaims.

1. A map of transmission slots for a port of a network element, the mapembodied in a computer-readable medium having computer-executableinstructions comprising: a plurality of hierarchical sets ofsubstantially evenly spaced port transmission slots; the hierarchicalsets comprising a plurality of parent sets each having its porttransmission slots divided between a plurality of child sets, the childsets comprising interleaved port transmission slots; wherein thehierarchical sets further comprise a plurality of primary hierarchicalsets and secondary hierarchical sets, the primary hierarchical sets eachcomprising substantially evenly spaced port transmission slots and anumber of port transmission slots corresponding to multiple of a basetransmission rate for the port transmission slots, the secondaryhierarchical sets comprising remaining port transmission slots.
 2. Themap of claim 1, further comprising each parent set having a same numberof child sets.
 3. The map of claim 1, the hierarchical sets furthercomprising a plurality of base sets, the base sets each having a numberof port transmission slots corresponding to a base transmission rate forthe port.
 4. A network element for a telecommunication system,comprising: a plurality of ports for connection to disparatetransmission lines; a map of port transmission slots for each of theports, the maps each comprising: a plurality of hierarchical sets ofsubstantially evenly spaced port transmission slots; the hierarchicalsets comprising a plurality of parent sets each having its porttransmission slots divided between a plurality of child sets, the childsets comprising interleaved port transmission slots; wherein thehierarchical sets further comprise a plurality of primary hierarchicalsets and secondary hierarchical sets, the primary hierarchical sets eachcomprising substantially evenly spaced port transmission slots and anumber of port transmission slots corresponding to multiple of a basetransmission rate for the port transmission slots, the secondaryhierarchical sets comprising remaining port transmission slots.
 5. Thenetwork element of claim 4, wherein each parent set has the same numberof child sets.
 6. The network element of claim 4, wherein thehierarchical sets further comprise a plurality of base sets, the basesets each having a number of port transmission slots corresponding to abase transmission rate for the port.